EDC - Unit 1
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Transcript of EDC - Unit 1
![Page 1: EDC - Unit 1](https://reader036.fdocuments.net/reader036/viewer/2022081715/546eb32bb4af9faa598b460e/html5/thumbnails/1.jpg)
ELECTRONIC DEVICES AND CIRCUITS
Faculty:
1.Shaik.Jakeer Hussain
2.P.Sandeep patil
3.P.Ramesh Babu
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UNIT-I
• ELECTRON DYNAMICS AND CRO: Motion of charged particles in electric and magnetic fields. Simple problems involving electric and magnetic fields only. Electrostatic and magnetic focusing. Principles of CRT, deflection sensitivity (Electrostatic and magnetic deflection), parallel and perpendicular electric and magnetic fields
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Deflection of Electrons in a Uniform Electric Field
• Consider an electron beam directed between two oppositely charged parallel plates as shown below.
• With a constant potential difference between the two deflecting plates, the trace is curved towards the positive plate.
+
-
d
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Deflection of Electrons in a Uniform Electric Field
• The force acting on each electron in the field is given by
d
eVeEF P
where E = electric field strength, V = p.d. between plates, d = plate spacing.
p
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Deflection of Electrons in a Uniform Electric Field
• The vertical displacement y is given by
22 )(2
1
2
1t
md
eVaty p
2
2
)(2
1
v
x
md
eVp
This is the equation for a parabola.
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Deflection of Electrons in a Uniform Magnetic Field
• The force F acting on an electron in a uniform magnetic field is given by
BevF
Since the magnetic force F is at right angles to the velocity direction, the electron moves rounda circular path.
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Deflection of Electrons in a Uniform Magnetic Field
• The centripetal acceleration of the electrons is
m
Beva
Hence m
Bev
r
va
2
which gives
eB
mvr
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Cathode Ray Oscilloscope (CRO)
• The structure of the cathode ray tube
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Cathode Ray Oscilloscope Controls
• Y-Gain
• Time Base
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Y-Gain
• amplifies the Y-deflection
• small input voltages are amplified by built-in amplifiers before applying to the Y-plates.
• Y- Gain = 0.5 V/div– 0.5 volt will cause a vertical deflection of 1
division
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Time Base
• is a saw-tooth voltage applied internally across the X-plates.
time
volts
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Time Base
• controls the speed at which the spot sweeps across the screen horizontally from left to right.
Time taken for spot to move across the screen and back
Fly backvolts
time0spot at centreof screen
spot on left sideof screen
spot on right sideof screen
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volts
time0
Screen
spot on left sideof screen
spot at centreof screen
spot on right sideof screen
Fly back
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Time Base
• it helps to display the actual waveform of any a.c. applied across the Y-plates
• normally calibrated in– s/cm– ms/cm s/cm
• gives the time required for the spot to sweep 1 cm horizontally across the screen.
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Time Base: How It Works
Time taken for spot to move across the screen and back
time
volts Fly back
0spot at centreof screen
spot on left sideof screen
spot on right sideof screen
A
B
C
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Uses of c.r.o.
• Measure potential difference– d.c.– a.c.
• Display waveforms of alternating p.d.
• Measure short intervals of time, and
• Compare frequencies
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Measuring d.c. Potential Difference
• switch off the time-base• a spot will be seen on the c.r.o. screen• d.c. to be measured is applied to the Y-
plates• spot will either deflected upwards or
downwards• deflection of the spot is proportional to
the d.c. voltage applied
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Measuring d.c. Potential Difference
Y-input
y
If the Y-gain control is set at 2 volts/division
And the vertical deflection, y, is 1.5
Then d.c. voltage
= 1.5 x 2
= 3.0 V
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Measuring a.c. voltage
• switch off the time-base• a spot will be seen on the c.r.o. screen• a.c. to be measured is applied to the Y-plates• spot will move up and down along the vertical
axis at the same frequency as the alternating voltage– spot moves to the top when the voltage increases to
its maximum (positive)– spot moves to the bottom when the voltage
decreases to its lowest (negative)
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Measuring a.c. voltage
• When the frequency is high– the spot will move so fast that a vertical line is
seen on the screen
• Length of the vertical line gives the peak-to-peak voltage (Vpp) applied to the Y-plate
• The peak voltage (Vp) is
= Vpp/2
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Measuring a.c. voltage
Y-input
Vpp
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Measuring a.c. voltage
Vpp
Vp Vp = Vpp/2
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C.R.O. as a Voltmeter
• it has nearly infinite resistance (between the X- and Y-plates), therefore draws very little current;
• it can be used to measure both d.c. and a.c. voltages; and
• it has an immediate response.
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Displaying Waveforms
• Set the time-base to a suitable frequency,
• Apply the input to the Y-plate– a steady waveform of the input will be
displayed on the c.r.o.
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Displaying Waveforms
Y-input
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Displaying Waveforms
• When input voltage frequency is the same as the time-base frequency
Input Voltage c.r.o. screen
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Displaying Waveforms
• When input voltage frequency is the twice the time-base frequency
Input Voltage c.r.o. screen
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Measuring Short Time Intervals
• Set time-base to its lowest frequency range
• Connect microphone to the Y-input
• Blow two short whistles into the microphone– two short pulses, at short interval apart will be
displayed on the c.r.o. screen
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Measuring Short Time Intervals
t divisions
If the time-base is 10 ms/division
and
if the separation between pulses
is t divisions
then
time interval is 10t ms
c.r.o. screen
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Measuring Short Time Intervals
Y-input
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Lissajous’ Figures
• Lissajous’ figure can be displayed by applying two a.c. signals simultaneously to the X-plates and Y-plates of an oscilloscope.
• As the frequency, amplitude and phase difference are altered, different patterns are seen on the screen of the CRO.
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Lissajous’ Figures
Same amplitude but different frequencies